High Color Expression Display Device and Method for Adjusting Displayed Color

ABSTRACT

A high color expression display device and a method for adjusting the displayed color are provided. The display device includes a backlight source, a transmittance adjusting layer, and a display panel for receiving light from the backlight source. The display panel has a color filter disposed above the backlight source. A CIE standard illuminant C test result of the color filter falls into a predetermined scope. In a transmittance spectrum of the transmittance adjusting layer, an average transmittance at wavelength shorter than 495 nm is smaller than that at wavelength greater than 570 nm.

This application claims the priority based on a Taiwanese PatentApplication No. 098102990, filed on Jan. 23, 2009, the disclosure ofwhich is incorporated herein by reference in its entirety.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates to a display device and a method foradjusting the displayed color; more particularly, the present inventionrelates to a high color expression display device and a method foradjusting the displayed color.

2. Description of the Prior Art

Display panels and panel display devices using the display panels havebecome the mainstream display devices. For example, various paneldisplays, home flat televisions, panel monitors of personal computersand laptop computers, and display screens of mobile phones and camerasare products widely using display panels. Particularly, the marketdemand for liquid crystal display devices largely increases in recentyears. In order to meet the function and appearance requirements ofliquid crystal displays, the design of backlight modules used in liquidcrystal display devices is also diverse.

In conventional, the backlight module usually uses tube lamps as thebacklight source. Light emitted from the tube lamp can achieve a certainlevel of color rendering and color saturation. However, since the tubelamp occupies a larger space, the backlight module equipped with thetube lamp accordingly has a larger volume. Additionally, the tube lampconsumes more power resulting in low usable time for the entire system.In order to address the above problems, some backlight modules use whitelight emitting diodes (LEDs) as the light source. The white LED isadvantageous in environmental protection, low power consumption, andsmall volume. However, the color expression and color saturation of thewhite LED still cannot match up those of the tube lamp. For example, thewhite LED made of a blue LED chip with yellow green phosphors usuallygenerates small energy in the red light range causing color shift in thegenerated white light.

Additionally, due to material properties and production limitations ofthe white LED, the availability of white LEDs is restricted. As shown inFIG. 1, due to various limitations, the available or suitable white LEDsare those having coordinates fallen into the area 10 (for example, inthe CIE 1931 coordinate system). However, in consideration of colorsaturation and expression of other colors, the practical white LEDs maybe those having coordinates fallen into the area 30. Since only half ofwhite LEDs in the area 30 will meet the limitations defined in the area10, the other half of white LEDs are not applicable which inevitablyincreases the production cost.

In order to address the white color shift issue and the difficulty inselecting or manufacturing suitable white LEDs, a color filter is oftenemployed for adjustment. However, with the addition of the color filter,the color shift, such as orange color shift or purple color shift, isreadily occurred and adversely affects the color rendering. Moreover,the addition of certain settings of color filter may diminish theoverall light transmittance and in turn undesirably affect thebrightness.

SUMMARY OF THE INVENTION

An objective of the present invention is to provide a display device anda method for adjusting the displayed color to achieve a better colorexpression and maintain the overall brightness.

Another objective of the present invention is to provide a displaydevice and a method for adjusting the displayed color, which may usewhite light emitting diodes (LEDs) with different color expression as abacklight source.

Another objective of the present invention is to provide a displaydevice and a method for adjusting the displayed color to reduce theproduction cost.

In one embodiment, the display device includes a backlight module, adisplay panel, and a transmittance adjusting layer. The display panel isdisposed above the backlight module and configured to receive lightemitted from the backlight module so as to produce images on the displaypanel. The transmittance adjusting layer is disposed above the backlightsource of the display module and configured to modulate the light of thebacklight source.

The display panel includes a color filter layer for filtering the lightof the backlight source. A result of the color filter layer under a CIEstandard illuminant C test includes:

0.135≦Bx≦0.150;

Ry≦0.329; and

Gx≦0.295;

wherein Bx is x coordinate of blue light obtained from the CIE standardilluminant C test, Ry is y coordinate of red light obtained from the CIEstandard illuminant C test, Gx is x coordinate of green light obtainedfrom the CIE standard illuminant C test.

The backlight module includes a backlight source therein. The backlightsource includes a plurality of white LEDs and has an intensity spectrumexhibiting a peak value within a peak range of wavelength shorter than495 nm being larger than that within in a peak range of wavelengthgreater than 570 nm. The transmittance adjusting layer has an averagetransmittance at wavelength being shorter than 495 nm smaller than thatat wavelength greater than 570 nm. By means of the method for adjustingthe displayed color, the transmittance adjusting layer is cooperatedwith the color filter layer to balance the weak intensity near the redlight wavelength range of the backlight source, so that the entiremodule can have a better performance when outputting white light andprevent white color shift. Additionally, each color of the output lightdoes not readily generate color shift, and the transmittance of lightcan be maintained or enhanced without affecting brightness.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 illustrates a schematic chromaticity diagram of a conventionalwhite LED;

FIG. 2 illustrates a schematic cross-sectional view of a display deviceof the present invention;

FIG. 3 is a schematic view of a backlight source in accordance with anembodiment of the present invention;

FIG. 4 is a schematic view of a transmittance adjusting layer on theouter surface of the second substrate in accordance with an embodimentof the present invention;

FIG. 5 is a schematic diagram showing the intensity spectrum of thebacklight source and the average transmittance of the transmittanceadjusting layer in accordance with an embodiment of the presentinvention;

FIG. 6A is a schematic view showing the color filter disposed betweenthe transmittance adjusting layer and the backlight module in accordancewith an embodiment of the present invention;

FIG. 6B is a schematic view showing the color filter disposed betweenthe transmittance adjusting layer and the backlight module in accordancewith another embodiment of the present invention;

FIG. 7 is a schematic view of the color filter layer disposed on thesecond substrate in accordance with an embodiment of the presentinvention;

FIG. 8 is a schematic view of a transmittance adjusting layer disposedwithin the second substrate in accordance with an embodiment of thepresent invention; and

FIG. 9 is a schematic view of a method for adjusting the displayedcolor.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT

The present invention provides a display device and a method foradjusting displayed color. In a preferred embodiment, the display deviceincludes a liquid crystal display device, such as liquid crystal displaytelevisions, liquid crystal display monitors of personal computers andlaptop computers, and liquid crystal display screens of mobile phonesand digital cameras.

As shown in FIG. 2, the display device preferably includes a backlightmodule 100, a display panel 200, and a transmittance adjusting layer700. In this embodiment, the backlight module 100 can be a direct typebacklight module; however, in a different embodiment, the backlightmodule 100 can include a light guide plate to form an edge typebacklight module. The display panel 200 is disposed on the backlightmodule 100 and configured to receive lights emitted from the backlightmodule 100. The display panel 200 is preferably a liquid crystal displayincluding a first substrate 210, a second substrate 230, and a liquidcrystal layer 250. In this embodiment, the first substrate 210 is asubstrate on the displaying side, and the second substrate 230 is asubstrate on the light incident side. However, in different embodiments,the first substrate 210 and the second substrate 230 can be disposed inan opposite manner. The liquid crystal layer 250 is sandwiched betweenthe first substrate 210 and the second substrate 230, and the behaviorof liquid crystal molecules thereof is controlled by the electrodes onthe first substrate 210 and the second substrate 230. By controlling thebehavior of the liquid crystal molecules, the display panel 200 iscapable of exhibiting different brightness at different pixels so thatimages to be viewed by users are formed. The transmittance adjustinglayer 700 is disposed above the backlight source 103 of the backlightmodule 100 and configured to receive the light of the backlight source103. In a preferred embodiment, the transmittance adjusting layer 700 isdisposed within the display panel 200; however, in differentembodiments. The transmittance adjusting layer 700 can be disposedoutside the display panel 200 or other locations as appropriate, such aswithin the backlight module 100.

In the embodiment of FIG. 2, the display panel 200 includes a colorfilter layer 300 which is disposed on an inner surface of the firstsubstrate 210. However, in a different embodiment, the color filterlayer 300 can be disposed on the second substrate 230 or other locationsabove the backlight source 103 of the backlight module 100. The colorfilter layer 300 is selective to light of different wavelength. That is,the color filter layer 300 allows light having a wavelength within in agiven range to pass therethrough and blocks light having otherwavelengths so that the display panel 200 is enabled to displaydifferent images. In this embodiment, the color filter layer 300preferably includes red, green, and blue resists, and the thicknessthereof is preferably between 1.4 μm and 2.5 μm to accommodate therequirements of manufacturing processes and other elements. Moreover,the color filter layer may include resists of other color, such yellow,magenta, etc.

The optical property of the color filter layer 300 is preferablyrepresented in accordance with the standard illuminant C test defined bythe International Commission on Illumination (CIE). Standard illuminantC is a CIE standard illuminant for filtered tungsten illumination thatsimulates average daylight with a correlated color temperature (CCT) of6774 degrees K. Besides directly performing the CIE standard illuminantC test, a standard illuminant A test can be performed to measure thetransmittance of the color filer layer 300, and the spectrum of the CIEstandard illuminant C can be then used to calculate the transmittancespectrum occurred when the illuminant C serves as the test light source.Thereafter, the chromatic value of the color filter layer 300 can beobtained. The standard illuminant A is a tungsten lamp with a colortemperature 2856 degrees K.

In a preferred embodiment, the result of the color filter layer 300under a CIE standard illuminant C test includes:

0.135≦Bx≦0.150;

Ry≦0.329; and

Gx≦0.295,

wherein Bx is x coordinate of blue light obtained from the CIE standardilluminant C test, Ry is y coordinate of red light obtained from the CIEstandard illuminant C test, and Gx is x coordinate of green lightobtained from the CIE standard illuminant C test.

In a preferred embodiment, the color filter layer 300 can be furthercontrolled to obtain BY≧16 under the CIE standard illuminant C test,wherein BY is the transmittance of blue light. With such an arrangement,the light transmittance of the display device can be improved toincrease the brightness. In a different embodiment, if the cooler filterlayer 300 is controlled to obtain By>0.120 under the CIE standardilluminant C test, a similar effect can be achieved, wherein By is ycoordinate of blue light obtained from the CIE standard illuminant Ctest.

The backlight source 103 of the backlight module 100 preferably includesa white light emitting diode (LED). In the embodiment of FIG. 2, thebacklight module 100 further includes an optical film 101, such asdiffusion plate, diffusion sheet, brightness enhancement film,polarizing film, disposed above the backlight source 103. The backlightmodule 100 can also include other optical elements such as reflectivesheet to be disposed corresponding to the backlight source 103 so as toimprove the brightness and uniformity of the backlight module 100. Asshown in FIG. 3, the white LED includes an active light source 110 and apassive light source 130. The active light source 110 can emit lightupon providing a signal, while the passive light source 130 is excitedby the light of the active light source 110 to generate light in anothercolor. In this embodiment, the active light source 110 is preferably ablue LED chip, and the passive light source 130 is a non-blue phosphor,particularly a phosphor with a wavelength greater than that of the blueLED chip. When the blue LED chip emits blue light incident onto thephosphor, the phosphor is excited to generate light in different colorso as to form a white light. In a preferred embodiment, the blue LEDchip is used with yellow green phosphor, such as yttrium aluminum garnet(YAG) phosphor or silicate phosphor. However, in a different embodiment,it can be used with other phosphors such as red and green phosphors. Inthis embodiment, the phosphors are doped within the transparent body 170of the bowel 150 of the white LED. In a different embodiment, thephosphors can be disposed (e.g. coated or adhered) at least on a partiallight exit surface of the blue LED chip.

In the embodiment of FIG. 2, the transmittance adjusting layer 700 isdisposed between the color filter layer 300 and the backlight nodule100. In other words, the color filter layer 300 receives lights of thebacklight module 100 through the transmittance adjusting layer 700. Inthis embodiment, the transmittance adjusting layer 700 is preferablydisposed on the inner surface of the second substrate 230, i.e. theinner surface of the second substrate 230 is the surface facing thefirst substrate 210. However, in a different embodiment, as shown inFIG. 4, the transmittance adjusting layer 700 can be disposed on anouter surface of the second substrate 230, i.e. the outer surface of thesecond substrate 230 is the surface facing the backlight module 100. Thetransmittance adjusting layer 700 preferably includes a transparentdielectric layer with a refractive index different from that of thesecond substrate 230 or the first substrate 210. The difference inrefractive index allows the transmittance adjusting layer 700 to havedifferent average transmittances for lights in different wavelengthrange. The transparent dielectric layer can include a material selectedfrom the group consisting of MgO, ZnO, SiN_(x), SiON_(x), TiO2, ZnSe,ZnS, TaO_(x), Al₂O₃, TeO_(x), ITO, Si₂O₃, MgF₂, SiO₂, LiF, or acombination thereof.

However, in a different embodiment, the transmittance adjusting layer700 can be a blue light absorption layer. That is, the transmittanceadjusting layer 700 can absorb a portion of blue light to achievedifferent average transmittances for lights in different wavelengthrange. In this embodiment, the blue light absorption layer can include amaterial selected from one of pigment and phosphor. The pigment can beselected from one of P.G.R254, P.G.R177, P.G.Y139, and P.G.Y150. Thephosphor can be selected from one of YAG, Y₂O₃:Eu, and Gd₃Al₅O₁₂:Ce₃ ⁺.Furthermore, the transmittance adjusting layer 700 can be formed bycoating, disposition, adhering, mixing, or other chemical or physicalprocesses as appropriate.

FIG. 5 illustrates an intensity spectrum of the backlight source 103 anda transmittance spectrum of the transmittance adjusting layer 700. Asshown in FIG. 5, when the backlight source 103 is made of a blue LEDchip with yellow green phosphors, the intensity spectrum preferablyexhibits a first peak range 510 and a second peak range 520, and eachpeak range has a peak value, which is a local maximum. For clarity, thelongitudinal axis on the left of FIG. 5 represents the relativeintensity. As shown in FIG. 5, the first peak range 510 is located onleft side near the blue light range, preferably on the area withwavelength less than 495 nm. The second peak range 520 is located onright side near the green light and red light ranges, preferably on thearea with wavelength greater than 495 nm. As shown in FIG. 5, since thisembodiment uses the blue LED chip as the active light source 110 togenerate blue light, which is then used to excite the passive lightsource 130 formed by phosphors to generate red and green lights, theintensity value in the first peak range 510 is preferably greater thanthat in the second peak range 520. Moreover, in the red light range withwavelength greater than 570 nm, the intensity is smaller and the peakvalue within this range is also smaller than that within the first peakrange 510. That is, the energy in the red light range is relativelysmaller compared to those in other color light range.

The traverse curve in FIG. 5 represents the average transmittance foreach range by referring to the longitudinal axis on the right hand side,which represents the transmittance. As shown in FIG. 5, thetransmittance adjusting layer 700 has an average transmittance atwavelength shorter than 495 nm (range A) being smaller than that atwavelength greater than 570 nm (range B). Since the transmittance curverepresents the average transmittance for each range, the transmittancein each range can be adjusted. In a preferred embodiment, the averagetransmittance at wavelength shorter than 495 nm is smaller than that atwavelength greater than 570 nm by at least 5%. However, in a differentembodiment, the difference in average transmittance is controlled to beat least 7%.

In cooperation with the transmittance adjusting layer 700 and the colorfilter layer 300, the weak intensity near the red light wavelength rangecan be balanced, so that coordinates (Wx, Wy) of the displayed light canbe maintained approximate to coordinates (0.313, 0.329) of the standardwhite light so that the entire module can achieve a better performancewhen outputting the white light and prevent the white color shift issue.Additionally, each color of the displayed light does not readilygenerate color shift, and the transmittance of light can be maintainedor enhanced without affecting the brightness.

Table 1 shows the test results on optical properties of the displayedcolor when the transmittance adjusting layer has a difference in averagetransmittance between ranges A and B to be respectively 5% and 7%, andthe color filter layer 300 is the same.

TABLE 1 test results when the difference in average transmittance is 5%and 7% Difference in average transmittance between ranges A and B Rx RyGx Gy Bx By Wx Wy 5% 0.597 0.346 0.326 0.554 0.150 0.143 0.310 0.333 7%0.597 0.346 0.327 0.554 0.150 0.143 0.312 0.334

From the test results in Table 1, in both conditions (i.e. thetransmittance adjusting layer has a difference in average transmittancebetween ranges A and B to be respectively 5% and 7%), the coordinates(Wx, Wy) of the output light are maintained appropriate to coordinates(0.313, 0.329) of the standard white light. The chromatic coordinates(Rx, Ry), (Gx, Gy), and (Bx, By) respectively for red, green, and bluecolors are also within a reasonable range without color shift.Particularly, both Ry and Bx are controlled within a reasonable rage nottoo large.

In the embodiment of FIG. 6A, the color filter layer 300 is disposedbetween the transmittance adjusting layer 700 and the backlight module100. In other words, the light of the backlight module 100 passesthrough the color filter layer 300 and then reaches the transmittanceadjusting layer 700. In this embodiment, the transmittance adjustinglayer 700 is disposed on the outer surface of the first substrate 210,i.e. the outer surface of the first substrate 210 is the surfaceopposite to the second substrate 230. The color filter layer 300 isdisposed on the inner surface of the first substrate 210 facing thesecond substrate 230. However, in a different embodiment, as shown inFIG. 6B, the transmittance adjusting layer 700 and the color filterlayer 300 can be sequentially stacked on the inner surface of the firstsubstrate 210. That is, the transmittance adjusting layer 700 isdisposed on the inner surface of the first substrate 210, and the colorfilter layer 300 is disposed on the transmittance adjusting layer 700.In the above embodiments, the transmittance adjusting layer 700 can be atransparent dielectric layer or a blue light absorption layer made ofpigment or phosphor.

In another embodiment, as shown in FIG. 7, the color filter layer 300can be formed on the inner surface of the second substrate 230, i.e. theinner surface of the second substrate 230 is the surface facing theliquid crystal layer 250, and the transmittance adjusting layer 700 canbe optionally disposed on the second substrate 230 or the firstsubstrate 210. As shown in FIG. 7, the transmittance adjusting layer 700is formed on the inner surface of the first substrate 210; however, indifferent embodiments, the transmittance adjusting layer 700 can beformed on the outer surface of the first substrate 210 or the innersurface or outer surface of the second substrate 230.

In the embodiment of FIG. 8, the transmittance adjusting layer 700 canbe formed within the second substrate 230. As shown in FIG. 8, thesecond substrate 230 is doped with pigments or phosphors to form thetransmittance adjusting layer 700. In this embodiment, the light of thebacklight module 100 passes through the transmittance adjusting layer700 and then reaches the color filter layer 300. By controlling thecomponents and concentration of the doped pigment or phosphor, thetransmittance adjusting layer 700 can be modified to have differentaverage transmittance for different wavelength range. Moreover, in adifferent embodiment, the transmittance adjusting layer 700 can beformed within the first substrate 210 by similar processes. In thiscase, the light of the backlight module 100 will pass through the colorfilter layer 300 and then reaches the transmittance adjusting layer 700.

The present invention also provides a method for adjusting displayedcolor of a display device. In the embodiment of FIG. 9, the step 910 ofthe method includes disposing a backlight source. In a preferredembodiment, the backlight source has an intensity spectrum exhibiting apeak value within a peak range of wavelength shorter than 495 nm beinglarger than that within in a peak range of wavelength greater than 570nm. In an embodiment, a white LED made of a blue LED chip with yellowgreen phosphors serves as the backlight source. For this backlightsource, except the blue light, light in other colors are generated byexciting the phosphors, and therefore, the intensity thereof will besmaller than that of the blue light. In the intensity spectrum, a peakrange of wavelength shorter than 495 nm is in the blue light range, andthe peak value thereof of larger than that of other peak range.

Step 930 includes disposing a display panel on the backlight source. Thedisplay panel includes a color filter layer. The result of the colorfilter layer under a CIE standard illuminant C test includes:

0.135≦Bx≦0.150;

Ry≦0.329; and

Gx≦0.295,

wherein Bx is x coordinate of blue light obtained from the CIE standardilluminant C test, Ry is y coordinate of red light obtained from the CIEstandard illuminant C test, and Gx is x coordinate of green lightobtained from the CIE standard illuminant C test. In a preferredembodiment, by changing material of the color filter layer, themanufacturing process, the thickness of the color resists, and thecomponent ratio of the color resists, optical properties obtained fromthe CIE standard illuminant C test of the color filter layer can becontrolled.

Moreover, in a preferred embodiment, the color filter layer iscontrolled to obtain BY≧16 under the CIE standard illuminant C test,wherein BY is a transmittance of blue light. With such an adjustment,the transmittance of output light of the display device can be increasedand the brightness is also enhanced.

Step 950 includes disposing a transmittance adjusting layer above thebacklight source. The transmittance adjusting layer has an averagetransmittance at wavelength shorter than 495 nm being smaller than thatat wavelength greater than 570 nm. In a preferred embodiment, thetransmittance adjusting layer is controlled to have the averagetransmittance at wavelength shorter than 495 nm being smaller than thatat wavelength greater than 570 nm by at least 5%. However, in adifferent embodiment, the difference in average transmittance is furthercontrolled to be at least 7%. By modifying material, thickness,structure, mixing ratio, etc. of the transmittance adjusting layer, thedifference can be adequately adjusted. Furthermore, the transmittanceadjusting layer can be formed by coating, disposition, adhering, mixing,or other chemical or physical processes as appropriate.

In this step, the transmittance adjusting layer can be disposed betweenthe color filter layer and the backlight source so that the color filterreceives the light of the backlight source through the transmittanceadjusting layer. In a preferred embodiment, when the color filter layeris disposed on the inner surface of a first substrate of the displaydevice, the transmittance adjusting layer can be disposed on the innersurface or the outer surface of a second substrate of the display panel.Furthermore, the transmittance adjusting layer can be disposed on thecolor filter layer. Moreover, the color filter layer can be disposed onthe inner surface of the second substrate, and the transmittanceadjusting layer is disposed on the outer surface of the secondsubstrate.

However, in another embodiment, when the color filter layer is disposedbetween the transmittance adjusting layer and the backlight source, thetransmittance adjusting layer can be disposed on the outer surface orthe inner surface of the first substrate, so that the color filter isdisposed on the second substrate. Moreover, the color filter layer andthe transmittance adjusting layer can be sequentially stacked on theinner surface of the second substrate. Furthermore, when thetransmittance adjusting layer is disposed on the outer surface of thefirst substrate, the color filter layer can be disposed on the innersurface of the first substrate.

Furthermore, the step 950 further includes forming a transparentdielectric layer to serve as the transmittance adjusting layer. Thetransparent dielectric layer has a refractive index different from thatof the first substrate or the second substrate. The difference inrefractive index allows the transmittance adjusting layer to havedifferent average transmittances for lights in different wavelengthrange. The transparent dielectric layer can include a material selectedfrom the group consisting of MgO, ZnO, SiN_(x), SiON_(x), TiO2, ZnSe,ZnS, TaO_(x), Al₂O₃, TeO_(x), ITO, Si₂O₃, MgF₂, SiO₂, LiF, or acombination thereof.

However, in a different embodiment, the step 950 can include forming ablue light absorption layer to serve as the transmittance adjustinglayer. That is, the transmittance adjusting layer can absorb a portionof blue light to achieve different average transmittances for lights indifferent wavelength range. In this embodiment, the blue lightabsorption layer can include a material selected from one of pigment andphosphor. The pigment can be selected from one of P.G.R254, P.G.R177,P.G.Y139, and P.G.Y150. The phosphor can be selected from one of YAG,Y₂O₃:Eu, and Gd₃Al₅O₁₂:Ce₃ ⁺.

In a different embodiment, the step 950 can further includes disposingthe transmittance adjusting layer within the second substrate. In thisembodiment, the second substrate is preferably mixed with the blue lightabsorption material, such as pigment or phosphor, and the secondsubstrate is then shaped for subsequent processes. By controlling thecomponent ratio and concentration of the pigment or phosphor within thesecond substrate, the transmittance adjusting layer can be modified tohave different average transmittance for different wavelength range.Moreover, the internal property of the second substrate can be modifiedby laser or other manners, so as to form the transmittance adjustinglayer within the second substrate.

The present invention has been described through the relevantembodiments above; however, the embodiments above are only exemplary.What needs to point out is that the embodiments disclosed are notintended to limit the scope of the present invention. Contrarily, themodifications and the equivalents included in the spirit and scope ofthe claims are all included in the scope of this invention.

What is claimed is:
 1. A display device, comprising: a backlight sourceincluding a plurality of white light emitting diodes; a display panelfor receiving light from the backlight source, wherein the display panelincludes a color filter layer, disposed above the backlight source, forfiltering the light of the backlight source, a result of the colorfilter layer under a CIE standard illuminant C test including:0.135≦Bx≦0.150; BY≧16; Ry≦0.329; and Gx≦0.295, wherein Bx is xcoordinate of blue light obtained from the CIE standard illuminant Ctest, Ry is y coordinate of red light obtained from the CIE standardilluminant C test, Gx is x coordinate of green light obtained from theCIE standard illuminant C test, BY is a transmittance of blue light; anda transmittance adjusting layer, disposed above the backlight source,for receiving the light of the backlight source, wherein thetransmittance adjusting layer has an average transmittance at wavelengthshorter than 495 nm being smaller than that at wavelength greater than570 nm.
 2. The display device of claim 1, wherein the transmittanceadjusting layer is disposed between the color filter layer and thebacklight source, and the color filter receives the light of thebacklight source through the transmittance adjusting layer.
 3. Thedisplay device of claim 2, wherein the display panel includes a firstsubstrate and a second substrate disposed opposite to each other, thetransmittance adjusting layer is formed within the second substrate. 4.The display device of claim 3, wherein the second substrate is mixedwith a blue light absorption material to from the transmittanceadjusting layer.
 5. The display device of claim 1, wherein the colorfilter layer is disposed between the transmittance adjusting layer andthe backlight source, the transmittance adjusting layer receives thelight of the backlight source through the color filter layer.
 6. Thedisplay device of claim 5, wherein the display panel includes a firstsubstrate and a second substrate disposed opposite to each other, thetransmittance adjusting layer is disposed on an outer surface of thefirst substrate opposite to the second substrate, and the color filterlayer is disposed on an inner surface of the first substrate facing thesecond substrate.
 7. A method for adjusting displayed color of a displaydevice, comprising: disposing a backlight source; disposing a displaypanel for receiving light from the backlight source, wherein the displaypanel includes a color filter layer, disposed above the backlightsource, for filtering the light of the backlight source, a result of thecolor filter layer under a CIE standard illuminant C test including:0.135≦Bx≦0.150; BY≧16; Ry≦0.329; and Gx≦0.295, wherein Bx is xcoordinate of blue light obtained from the CIE standard illuminant Ctest, Ry is y coordinate of red light obtained from the CIE standardilluminant C test, Gx is x coordinate of green light obtained from theCIE standard illuminant C test, BY is a transmittance of blue light; anddisposing a transmittance adjusting layer above the backlight source toreceive the light of the backlight source, wherein the transmittanceadjusting layer has an average transmittance at wavelength shorter than495 nm being smaller than that at wavelength greater than 570 nm.
 8. Themethod of claim 7, wherein the step of disposing the transmittanceadjusting layer includes disposing the transmittance adjusting layerbetween the color filter layer and the backlight source so that thecolor filter receives the light of the backlight source through thetransmittance adjusting layer.
 9. The method of claim 8, wherein thestep of disposing the transmittance adjusting layer includes disposingthe transmittance adjusting layer within a second substrate.
 10. Themethod of claim 9, wherein the step of disposing the transmittanceadjusting layer includes mixing a blue light absorption material withinthe second substrate to from the transmittance adjusting layer.
 11. Themethod of claim 7, wherein the transmittance adjusting layer is disposedin a manner that the color filter layer is between the transmittanceadjusting layer and the backlight source, and the transmittanceadjusting layer receives the light of the backlight source through thecolor filter layer.
 12. The method of claim 11, wherein the displaypanel is disposed in a manner that the color filter layer is disposed onan inner surface of a first substrate of the panel display, and the stepof disposing the transmittance adjusting layer includes disposing thetransmittance adjusting layer on an outer surface of the firstsubstrate.